EP2778432A1 - Flow rectifier - Google Patents

Abstract

The device has a guide inlet opening that is configured on a suction side at an axial height in front of a flow inlet opening (15) of a bar structure and formed with opening surface smaller than flow inlet opening. The bar structure is formed by a grid structure consisting of intersecting grid bars with the grid openings enclosed by grid bars. The grid bars are provided such that the ratio of height to thickness of grid bars is greater than 5. The grid openings are provided such that the ratio of a peripheral grid width to radial width of openings lies in a range between 1/ 3-3.

Description

The present invention relates to a flow rectifier for a fan assembly comprising a web structure of Luftleitstegen which can be fastened on the suction side in front of a flow inlet opening about a longitudinal axis of the fan arrangement, such that an inflow opening is formed on the suction side at an axial height in front of the flow inlet opening of the web structure Opening area is smaller than an opening area of the flow inlet opening.

Such a flow straightener is from the DE 105 26 24 known. In this case, arranged on a suction nozzle of a fan assembly star-shaped baffles, which are web-shaped, wherein the baffles are recognized in the outer curvature region of the suction nozzle and protrude against the flow direction umbrella-shaped from the suction nozzle as a whole. In this case, the baffles do not extend to a middle star point, so that an inflow opening, which contains no baffles, is present. In this known flow straightener, the noise level in the low-frequency frequency range is not reduced enough, which affects in particular the blade turning tones.

From the EP 0 547 253 is a flow straightener for a fan known, wherein this comprises a spanned in a plane perpendicular to the longitudinal axis extending grid, which is distributed from a plurality of concentric radially spaced-apart ring lands and eight in the circumferential direction arranged axial webs, wherein the axial webs connect the ring lands with each other and with an inner, a mounting opening surrounding retaining ring and with an outer retaining ring. In this known flow straightener, however, a high pressure loss is present, which is reflected in an increase in the required power consumption.

Based on the above-described prior art, the invention is based on the object, both the turbulence in the inflow and thus the low-frequency noise, especially to reduce the turning tones and to minimize the pressure drop of the rectifier.

According to the invention this is achieved in that the web structure is formed by a lattice structure of intersecting lattice webs, which has a plurality of lattice openings enclosed by the lattice webs, wherein the lattice structure forms a lateral surface of a geometric body. In this case, it is particularly advantageous if the axial height is dimensioned such that 0.05 ≦ H / D _If ≦ 0.5, where D _{If is} the outer diameter of the impeller of the fan assembly. Advantageously, the geometric body has the shape of a truncated cone or of an n-side truncated pyramid, where n is an integer and greater than or equal to 3. It is inventively advantageous if the frusto-conical body has a circular base and a circular end surface. Conveniently, the grid openings may have a polygonal or an oval shape. Furthermore, it is according to the invention advantageous if the lateral surface of the frusto-conical body viewed in longitudinal section along the longitudinal axis outwardly convex runs. However, it is also within the scope of the invention if this lateral surface has a concave profile.

The invention is based on the finding that the configuration of the grid structure according to the invention uniforms the inflow by reducing turbulence. Become through the walls formed by the grid bars Speed fluctuations perpendicular to the main flow direction impeded. About the distance of the walls to each other, this influence can be controlled, while at the same time it is important that the pressure loss caused by the web structure according to the invention is minimized. According to the invention, it is particularly advantageous that the inlet opening has no webs, as this pressure losses are prevented in this area.

Further advantageous embodiments of the invention are contained in the subclaims and will be explained in more detail with reference to the embodiments illustrated in the accompanying drawings.

Furthermore, the present invention relates to a fan assembly with a flow straightener according to the invention.

Fig. 1

eine perspektivische Ansicht einer Ventilatoranordnung mit einem erfindungsgemäßen Strömungsgleichrichter, zum Teil geschnitten,

Fig. 2

eine Detailansicht bei II in Fig. 1,

Fig. 3

eine perspektivische Ansicht auf einen erfindungsgemäßen Strömungsgleichrichter gemäß Fig. 1,

Fig. 4

eine perspektivische Ansicht auf die Rückseite des Strömungsgleichrichter gemäß Fig.3,

Fig. 5

eine weitere Ausführungsform einer Ventilatoranordnung mit einem erfindungsgemäßen Strömungsgleichrichter,

Fig. 6

eine perspektivische Vorderansicht auf den erfindungsgemäßen Strömungsgleichrichter gemäß Fig. 5,

Fig. 7

eine perspektivische Ansicht des Strömungsgleichrichters gemäß Fig. 6 von seiner Rückseite,

Fig. 8

eine perspektivische Ansicht einer weiteren Ausführungsform eines erfindungsgemäßen Strömungsgleichrichters,

Fig. 9

eine Rückansicht auf den erfindungsgemäßen Strömungsgleichrichter gemäß Fig. 8,

Fig. 10

eine perspektivische Ansicht auf den erfindungsgemäßen Strömungsgleichrichter gemäß Fig. 8, jedoch zum Teil geschnitten,

Fig. 11

Messkurven der Schallleistung in Abhängigkeit vom A-Pegel und

Fig. 12

eine typische Einbausituation eines Ventilators für die Messung der Schallleistung.

Show it:

Fig. 1

a perspective view of a fan assembly with a flow straightener according to the invention, partly in section,

Fig. 2

a detailed view at II in Fig. 1 .

Fig. 3

a perspective view of a flow straightener according to the invention according to Fig. 1 .

Fig. 4

a perspective view of the back of the flow straightener according to Figure 3 .

Fig. 5

a further embodiment of a fan arrangement with a flow rectifier according to the invention,

Fig. 6

a front perspective view of the flow straightener according to the invention according to Fig. 5 .

Fig. 7

a perspective view of the flow straightener according to Fig. 6 from his back,

Fig. 8

a perspective view of another embodiment of a flow straightener according to the invention,

Fig. 9

a rear view of the inventive flow straightener according to Fig. 8 .

Fig. 10

a perspective view of the flow straightener according to the invention according to Fig. 8 , but partially cut,

Fig. 11

Traces of the sound power as a function of the A level and

Fig. 12

a typical installation situation of a fan for measuring the sound power.

In the Fig. 1 to 10 the same parts or functionally identical parts are always identified by the same reference numerals. If certain described and / or removable from the drawings features of the flow straightener according to the invention or its components are described only in connection with an embodiment, but these are also essential according to the invention regardless of this embodiment as a single feature or in combination with other features of the embodiment and are claimed as belonging to the invention.

In Fig. 1 a fan assembly 1 is shown having an axial fan 2, a paddle wheel 3 and a centrally disposed hub 4, and on the periphery of the hub. 4 attached, radially to a central longitudinal axis XX extending blades 5 has. The central longitudinal axis XX coincides with an axis of rotation of the hub 4, wherein the hub 4 is designed in particular as an external rotor rotor of an external electric rotor motor 6.

The impeller 5 is circumferentially enclosed by a preferably circular cylindrical housing ring 7, on the suction side of a flow inlet opening 10 of the housing ring 7 an annular suction nozzle 8 is provided, which may preferably be integrally formed with the housing ring 7. On the suction side in the suction direction Y in front of the suction nozzle 8, a mounting plate 9 is arranged, which surrounds the flow inlet opening 10. In the suction direction Y in front of the flow inlet opening 10, an inventive flow rectifier 11 is attached, see also Fig. 2 to 4 , This flow rectifier 11 has a grid structure 12 of intersecting webs, in particular axial webs 14 which extend in the direction of the longitudinal axis XX and from in particular concentric to the longitudinal axis XX extending, annular peripheral webs 15. This grid structure 12 has 15 grid openings 15a between the axial webs 14 and the peripheral webs. The lattice structure 12 according to the invention forms a geometric body, wherein in the illustrated embodiment, the geometric body has the shape of a truncated cone whose base surrounds the flow inlet opening 10 and its end surface opposite the base surface comprises or comprises an inflow opening 16. It is advantageous if the axial webs 14 with the peripheral webs 15 include an angle α of 90 ° ± 10% deviation at their intersections. In the illustrated embodiment, the grid openings 15a are rectangular, in particular with curved peripheral sides, which are formed by the peripheral webs 15 in sections. However, the grid openings 15a may also have a different polygonal shape or have an oval shape. In the illustrated embodiment, the lateral surface of the frusto-conical body, which is formed by the lattice structure 12, seen in longitudinal section through its longitudinal axis XX outwardly convex convex. It can also according to the invention of Be advantageous if the lateral surface of the frusto-conical body of the lattice structure 12 curved inwards concave runs or has a straight course. In the illustrated embodiment, an inflow opening 16 is formed centrally and centrically to the longitudinal axis XX in the lattice structure 12. This inflow opening 16 has no webs. Preferably, the lattice structure 12 with a circumferential annular edge web 16a in the mounted state on the mounting plate 9 on the entire surface, so that the edge web 16a is formed such that it is parallel to the mounting plate 9 in the assembled state, ie it is perpendicular to the longitudinal axis XX. The axial webs 14 extend from the edge web 16a counter to the suction direction Y in the direction of the inflow opening 16. The axial webs 14 advantageously have extensions 17, with which they embrace the flow inlet opening 10 in its edge region 18 in the assembled state, see Fig. 4 , The middle, in particular web-free inlet opening 16 has an inner diameter D _i , wherein in particular D _i ≥ D _If x 0.55, wherein the diameter D _{If is} the maximum outer diameter of the impeller. The webs, ie the axial webs 14 and the peripheral webs 15 of the lattice structure 12 preferably have a web height H _f and a web thickness T _f , where H _f / T _f > 5. The lattice openings 15a have an axial width L _r and a circumferential lattice width L _i ", where preferably ⅓ <L _u / L _r <3. In this case, the lattice openings 15a have a diagonal opening width L _d , which is dimensioned such that 0, 01 <L _d / D _If <0.15, where D _{If is} the diameter of the impeller, ie the impeller 3. The axial height H of the inflow opening 16 to the base of the fin structure 12 or mounting plate 9 is calculated from 0.05 ≤ H / D _If ≤ 0.5.

Conveniently, the axial webs 14 always have the same circumferential distance to each other, and the peripheral webs 15 expediently always have the same axial distance from each other. It is also within the scope of the invention if the grid width L _d and / or the ratio L _U / L _r varies over the radius and / or over the circumference of the grid structure 12. Also, areas of the grid structure 12 may be open, so that there are no webs. Furthermore, it is within the scope of the invention, when the distribution of the axial webs 14 and / or the peripheral webs 15 is not uniform but uneven within the lattice structure 12 according to the invention.

The inlet opening 16 of the flow rectifier 11 is expediently enclosed by a peripheral web 15, so that the axial webs 14 end at this peripheral web 15. At the outer edge web 16 a fastening tabs 19 are advantageously integrally formed with through holes, wherein the flow straightener 11 is attached to the mounting plate 9 by means not shown fastening means and the fastening tabs 18.

In Fig. 5 a fan assembly 1 is shown, which has a radial fan 20. This has a paddle wheel 21 with a centrally located hub 22. On the hub 22 blades 23 are attached. The axis of rotation of the hub 22 coincides with the central longitudinal axis XX of the fan assembly 1. The drive is expediently an electric external rotor motor whose rotor simultaneously forms the hub 22.

The impeller 21 is inter alia of a cover plate 24. At this suction side of the flow inlet opening 10, which is enclosed by the cover plate 24, an annular suction nozzle 8 is arranged. This suction nozzle 8 is, as in Fig. 1 , from a cylindrical portion 8a, which adjoins the cover plate 24 in the example shown and may be connected to the mounting wall 9 with a section, and an arcuate flared nozzle portion 8b, which extends to the mounting wall 9, formed. How to Fig. 1 described, in the suction direction Y in front of the flow inlet opening 10, an inventive flow straightener 11, arranged, see also Fig. 6 , This consists of Axialstegen 14 and peripheral webs 15, including in full on the description of the Fig. 1 to 4 Reference is made, as well as in full extent to the design information with respect to the dimensioning of the webs, ie the axial webs 14 and the peripheral webs 15 and the dimensioning of the grid openings 15a.

Like from the Fig. 5 to 7 can be seen, the flow straightener 11 can be attached with its peripheral edge web 16a on the mounting plate 9 under surface contact, including provided in the edge web 16a through holes 19 for fastening means.

In the Fig. 8 to 10 a further embodiment according to the invention of a flow rectifier 11 is shown, in which the flow rectifier 11 is formed integrally with the suction nozzle 8. In this embodiment, the edge web 16 according to the Fig. 5 to 7 omitted, and the axial webs 14 are connected at their ends directly to the suction nozzle 8 in the region of its nozzle portion 8b. In this variant, the suction nozzle 8 has an annular flange section 8c on the section 8b, which can be fastened directly to the mounting wall 9.

The flow rectifier 11 according to the invention can be produced by injection molding, die casting from one or more parts. These individual parts can be riveted, glued or welded or screwed. Also, a snap connection would be possible within the scope of the invention. If it concerns metal parts in the flow straightener according to the invention, these can also be produced by punching. As in particular to the Fig. 8 to 10 is described, the flow straightener 11 according to the invention can also be screwed, glued, riveted or connected by a clip connection with the suction nozzle section or an inlet ring of a housing of the fan assembly according to the invention or with the wall ring. Also, a weld could be possible. The lattice structure 12 according to the invention may consist of plastic, of metal or of composite materials. According to the invention, it may also be advantageous if the flow rectifier 11 according to the invention is provided with a flameproof coating. It is also possible to select the manufacturing material accordingly, so that the conditions of fire protection are met.

Advantageously, the lattice webs, in particular the axial webs 14 and the peripheral webs 15 of the lattice structure 12 according to the invention are designed and arranged such that the flow emerging from the flow rectifier 11 according to the invention is swirl-free or that no swirl is supplied by the lattice structure 12 according to the invention. It is also within the scope of the invention if the inner diameter D _{i of} the inlet opening 10 varies over the circumference of the opening. In order to achieve a contact protection, it may also be expedient if the inlet opening 10 is closed by a protective grid. The flow rectifier 11 according to the invention may also, if appropriate, be attached to the suction side, in particular for assembly reasons, directly on a supporting or protective grid of a fan or fan arrangement. The inflow opening 16 can also accommodate further elements, provided that their entire flow area does not occupy greater than 15% of the area of the inflow opening 16. Thus, it is possible, for example, that a holder for mounting the fan is present within the inflow opening 16.

Compared to the prior art described above results in a significant reduction of the rotation of the fan, both in the non-installed state and in the installed state. In addition, there is a significant reduction of the weighted sound power level when installed, with no or minimal efficiency degradation.

As it turned out Fig. 11 can be seen, a significant noise advantage is achieved by the use of a flow straightener according to the invention. The curve A shows a one-third band of the suction-side sound power of an axial fan at a flow rate of 14400m ³ / h and a pressure of 58 Pa. The speed is 1020 1 / min with undisturbed flow under laboratory conditions. Undisturbed inflow here means a flow having a spatially and temporally uniform velocity field which has a low degree of turbulence of less than 1%.

A typical schematic installation situation of the same fan or fan 2 in a customer device, wherein the fan sucks air through a heat exchanger 26, and between the heat exchanger 26 and fan 2 is a free space 27 which is enclosed by a box 28 is in Fig. 12 shown. Usually there is behind the axial fan nor a protective grid, not shown here. The heat exchanger has the dimensions: length 141 cm x height 153 cm x depth 17 cm, the pressure loss is 58Pa at 14400 m ³ / h. The box 28 or clearance 27 has the same height and length at a depth of 38 cm.

Through this installation, the fan has a disturbed inflow due to a temporally and locally uneven speed field. In addition, the turbulence of the inflow is significantly increased. Curve B reflects this case, from which it can be seen that the noise of the fan is greatly increased, especially at low frequencies. By using a flow straightener according to the invention with the dimensions: outer diameter 795 mm, inner diameter 464 mm, height 130 mm; L _d / D _If = 4.3%; 15 circumferential struts 15 and 120 axial struts 14, strut depth 17 mm and strut thickness 1.5 mm, the noise level is again adjusted to that of the undisturbed inflow (curve A), which is referred to curve C. By using a flow straightener according to the invention, a temporally and spatially disturbed inflow is evened out and the turbulence is substantially reduced. This has a marked effect on noise reduction, so that the use of a flow rectifier according to the invention ensures that the inflow is substantially equalized again to the undisturbed inflow. Thus, an inventive flow straightener brings significant noise advantages.

The invention is not limited to the illustrated and described embodiments, but also includes all the same in the context of the invention embodiments. Furthermore, the invention has hitherto not been limited to the feature combinations defined in the claims, but can also be achieved by any other combination of certain features of all to be defined as a whole. This means that in principle virtually every individual feature of the independent claims can be omitted or replaced by at least one individual feature disclosed elsewhere in the application. In this respect, the claims are to be understood merely as a first formulation attempt for an invention.

LIST OF REFERENCE NUMBERS

1 fan arrangement 2 Axial 3 paddle wheel 4 hub 5 shovel 6 External rotor motor 7 housing ring 8th suction nozzle 8a Cylindrical section 8b nozzle section 8c annular flange 9 mounting plate 10 Flow inlet opening 11 Flow straightener 12 lattice structure 14 axial webs 15 circumferential lands 15a grid openings 16 inlet opening 16a edge web 17 projections 18 border area 19 mounting tabs 20 centrifugal fan 21 paddle wheel 22 hub 23 shovel 24 cover disc 26 heat exchangers 27 free space 28 box X X longitudinal axis Y suction D _i Inner diameter D _a outer diameter D _If Diameter impeller H _f Base height T _f web thickness L _r radial width L _u circumferential grid width L _d diagonal opening width α angular width

Claims (26)

Flow rectifier (11) for a fan assembly (1), comprising a web structure (12) of Luftleitstegen (14) attachable to the suction side before a flow inlet opening (10) with a central longitudinal axis (XX) of the fan assembly (1), the flow inlet opening (10) such encloses that on the suction side at an axial height (H) in front of the flow inlet opening (10) of the web structure (12) an inflow opening (16) is formed whose opening area is smaller than the opening area of the flow inlet opening (10),
characterized in that the web structure of a grid structure (12) of intersecting grid bars (14, 15) is formed, which has a plurality of the grid bars (14, 15) enclosed grid openings (15a), wherein the grid structure (12) has a lateral surface forms a geometric body. Flow rectifier (11) according to claim 1,
characterized in that the axial height (H) is calculated from the ratio 0.05 ≤ H / D _If ≤ 0.5, where D _{If is} the outer diameter of an impeller (3) of the fan assembly (1). Flow rectifier (11) according to claim 1 or 2,
characterized in that the geometric body has the shape of a truncated cone whose base has the flow inlet opening (10) and whose base surface opposite the end face the inflow opening (16). Flow rectifier (11) according to claim 1 or 2,
characterized in that the geometric body has the shape of an n-side truncated pyramid whose base has the flow inlet opening (10) and whose base surface opposite end face the inflow opening (16), wherein n is greater than / equal to 3 and integer. Flow rectifier (11) according to claim 3,
characterized in that the frustoconical body has a circular end surface and base. Flow rectifier (11) according to claim 4,
characterized in that n = 4 and the base surface and the end surface have the shape of a square. Flow rectifier (11) according to one of claims 1 to 6,
characterized in that the grid openings (15a) have a polygonal or an oval shape. Flow rectifier (11) according to one of claims 1 to 7,
characterized in that the lateral surface of the frusto-conical body or the side surface of the truncated pyramidal, n-side body viewed in longitudinal section through its longitudinal axis (XX) convex to the outside convex or concave inwardly concave. Flow rectifier (11) according to one of claims 1 to 8,
characterized in that the grid structure (12) extending in the direction of the flow inlet opening (10) to the inlet opening (16) extending axial webs (14) and this preferably at an angle (α) of 90 ° ± 10% deviation circumferential webs (15) is formed. Flow rectifier (11) according to one of claims 1 to 9,
characterized in that the axial webs (14) are connected with their counter to the flow direction (Y) facing ends with a peripheral ridge (15) which surrounds the inlet opening (16) and are connected at its other end with a circular edge web (16 a). Flow rectifier (11) according to one of claims 1 to 10,
characterized in that the middle inflow opening (16) is preferably web-free and has an inner diameter (D _i ), wherein in particular D _i ≥ D _If x 0.55, where D _{If is} the Lauffraddurchmesser. Flow rectifier (11) according to one of claims 1 to 11,
characterized in that the distance between the axial webs (14) is equal to each other. Flow rectifier (11) according to one of claims 1 to 12,
characterized in that the distance between the circumferential webs (15) is equal to each other. Flow rectifier (11) according to one of claims 1 to 13,
characterized in that the lattice webs (14, 15) of the lattice structure (12) have a web height (H _f ) and have a web thickness (T _f ), where H _f / T _f > 5. Flow rectifier (11) according to one of claims 1 to 14,
characterized in that the grid openings (15a) have a radial width (L _r ) and a circumferential grid width (L _u ), where ⅓ <L _u / L _r <3. Flow rectifier (11) according to one of claims 1 to 15,
characterized in that the grid openings (15a) have a diagonal opening width (L _d ) and the fan assembly (1) has an impeller (5) with an impeller diameter (D _If ), where 0.01 <L _d / D _If <0 , 15th Flow rectifier (11) according to one of claims 1 to 16,
characterized in that the grid structure (12) has a circumferential annular edge web (16a) with which it rests in the mounted state on a mounting plate (9) of a fan assembly (1) over the entire surface, so that the edge web (16a) perpendicular to the longitudinal axis (XX ) is aligned. Flow rectifier (11) according to one of claims 1 to 17,
characterized in that the grid width (L _d ) and / or the ratio L _u / L _r varies over the radius and / or over the circumference of the grid structure (12). Flow rectifier (11) according to one of claims 1 to 18,
characterized in that areas of the grid structure (12) are open. Flow rectifier (11) according to one of claims 9 to 19,
characterized in that the distribution of the axial webs (14) and / or the peripheral webs (15) is non-uniform in the region of the lattice structure (12). Flow rectifier (11) according to one of claims 9 to 20,
characterized in that the inflow opening (16) of the flow rectifier (11) is enclosed by a peripheral web (15) so that the axial webs (14) terminate at this peripheral web (15). Flow rectifier (11) according to one of claims 1 to 21,
characterized in that the flow rectifier (11) is integrally formed with a suction nozzle (8), so that the grid structure (12), in particular the axial webs (14) with the suction nozzle (8) in the region of its nozzle portion (8b) is / are connected and the suction nozzle (8) is connectable to the fan assembly (1). Flow rectifier (11) according to one of claims 1 to 23,
characterized in that the grid structure (12) is made as an injection molded part. Flow rectifier (11) according to one of claims 1 to 23,
characterized in that the grid structure (12) is composed in one piece or of several parts, wherein the individual parts can be riveted together, glued, welded, screwed or locked. Flow rectifier (11) according to one of claims 1 to 24,
characterized in that in the inflow opening (16) further components are included, the total effective flow area ≤ 15% of the flow area of the inflow opening (16). Fan arrangement (1), consisting of an axial, radial or diagonal fan (2, 20) with a paddle wheel (3, 21), which is enclosed by a housing, on the suction side at a flow inlet opening (10) a suction nozzle (8) and in the suction direction (Y) in front of the flow inlet opening (10) a flow rectifier (11) are arranged,
characterized by a flow rectifier (11) according to one or more of claims 1 to 25.

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